Concentrating solar energy collector

ABSTRACT

Systems, methods, and apparatus by which solar energy may be collected to provide electricity or a combination of heat and electricity are disclosed herein.

CROSS REFERENCE TO RELATED APPLICATIONS

This application is a continuation of U.S. patent application Ser. No. 12/781,706 filed May 17, 2010 and titled “Concentrating Solar Energy Collector,” which is incorporated herein by reference in its entirety.

FIELD OF THE INVENTION

The invention relates generally to the collection of solar energy to provide electric power, heat, or electric power and heat.

BACKGROUND

Alternate sources of energy are needed to satisfy ever increasing world-wide energy demands. Solar energy resources are sufficient in many geographical regions to satisfy such demands, in part, by provision of electric power and useful heat.

SUMMARY

Systems, methods, and apparatus by which solar energy may be collected to provide electricity, heat, or a combination of electricity and heat are disclosed herein.

In one aspect, a concentrating solar energy collector comprises a linearly extending receiver, a linearly extending reflector oriented parallel to a long axis of the receiver and fixed in position with respect to the receiver, and a linearly extending support structure supporting the receiver and the reflector and pivotally mounted to accommodate rotation of the support structure, the reflector, and the receiver about a rotation axis parallel to the long axis of the receiver. The linearly extending support structure comprises three longitudinal members oriented parallel to the rotation axis, extending at least substantially the length of the reflector, and arranged to form a framework having a triangular cross-section perpendicular to the rotation axis.

In some variations of this aspect, the rotational axis is coincident or substantially coincident with one of the three longitudinal members. In addition, or alternatively, a first one of the longitudinal members may be located on a reflective side of the reflector and the other two longitudinal members located on an opposite side of the reflector from the first longitudinal member.

In further variations comprising the features of any of the above variations of this aspect, the support structure may comprises a first plurality of diagonal members connecting a first one of the longitudinal members to a second one of the longitudinal members, and a second plurality of diagonal members connecting the first longitudinal member to the third one of the longitudinal members. The support structure may also, or alternatively, comprise a plurality of transverse plates, each transverse plate oriented perpendicular to and connecting the three longitudinal members. In variations comprising the diagonals and the transverse plates, the first plurality of diagonal members may each connect a joint between a corresponding one of the transverse plates and a first one of the longitudinal members to a joint between an adjacent transverse plate and a second one of the longitudinal members. Similarly, the second plurality of diagonal members may each connect a joint between a corresponding one of the transverse plates and a first one of the longitudinal members to a joint between an adjacent transverse plate and the third one of the longitudinal members. In such variations, the plurality of transverse plates, the first plurality of diagonals, and the second plurality of diagonals may together form a repeating pattern along the longitudinal members.

In further variations comprising the features of any of the above variations of this aspect, the reflector may comprise a plurality of linearly extending reflective elements oriented parallel to the long axis of the receiver and fixed in position with respect to each other and with respect to the receiver. The support structure may comprise a plurality of separate longitudinal reflector supports each of which has a long axis oriented parallel to the rotation axis and each of which comprises a channel portion parallel to its long axis, a first (optionally, planar) lip portion on one side of and parallel to the channel portion, and a second (optionally, planar) lip portion parallel to and on an opposite side of the channel portion from the first lip portion. Each reflective element may be attached to and supported by the lip portions, and bridge the channel portion, of a corresponding one of the longitudinal reflector supports. The support structure may also comprise a plurality of transverse reflector supports extending away from the rotation axis. Each transverse reflector support may comprise a plurality of notches, with each notch in a transverse reflector support corresponding to a separate longitudinal reflector support. In such variations, the channel portion of each longitudinal reflector support may be positioned in corresponding notches of the transverse reflector supports with the lip portions of each longitudinal reflector support in contact with and supported by surfaces of the transverse reflector supports adjacent to the corresponding notches.

In further variations comprising the features of any of the above variations of this aspect, the reflector may comprise a plurality of linearly extending reflective elements oriented parallel to the long axis of the receiver and fixed in position with respect to each other and with respect to the receiver. Each linearly extending reflective element may comprise a low-iron glass layer having a first surface and a second surface, with the first surface oriented facing the receiver, a reflective layer disposed on the second surface of the low-iron glass layer, an adhesive disposed on the reflective layer, and a second glass layer attached by the adhesive to the reflective layer, to the low-iron glass layer, or to both the reflective layer and the low-iron glass layer.

In further variations comprising the features of any of the above variations of this aspect, the reflector may comprise a plurality of linearly extending reflective elements oriented parallel to the long axis of the receiver and fixed in position with respect to each other and with respect to the receiver. The linearly extending reflective elements may be of at least two different lengths and arranged in parallel side-by side rows, with each row including two or more of the linearly extending reflective elements arranged end-to-end, such that gaps or joints between the reflective elements in one row are not next to gaps or joints between reflective elements in an adjacent row. In some of these variations, no gaps or joints between reflective elements in any row are next to gaps or joints between reflective elements in any adjacent row. In some variations, the majority of gaps or joints between reflective elements in any row are not adjacent to gaps or joints between reflective elements in any adjacent row.

In further variations comprising the features of any of the above variations of this aspect, the receiver may comprise solar cells. In such variations, the receiver may also comprise coolant channels accommodating flow of liquid coolant in thermal contact with the solar cells. In alternative further variations based on any of the above variations, except for that just preceding this variation, the receiver may accommodate flow of a liquid to be heated by solar energy concentrated on the receiver, but lack solar cells.

In further variations comprising the features of any of the above variations of this aspect that comprise transverse reflector supports and transverse plates, the transverse reflector supports may be attached to corresponding ones of the transverse plates.

In further variations comprising the features of any of the above variations of this aspect, the reflector may be a parabolic reflector. In further variations based on any of the above variations of this aspect in which the reflector comprises a plurality of linear reflective elements, the linear reflective elements may together form a parabolic reflector.

In further variations comprising the features of any of the above variations of this aspect in which the reflector comprises a plurality of linear reflective elements, the linearly extending reflective elements may be flat or substantially flat.

In another aspect, a concentrating solar energy collector comprises a linearly extending receiver, a plurality of linearly extending reflective elements oriented parallel to a long axis of the receiver and fixed in position with respect to each other and with respect to the receiver, and a linearly extending support structure supporting the receiver and the reflective elements and pivotally mounted to accommodate rotation of the support structure, the reflective elements, and the receiver about a rotation axis parallel to the long axis of the receiver. The support structure comprises a plurality of separate longitudinal reflector supports each of which has a long axis oriented parallel to the rotation axis and each of which comprises a channel portion parallel to its long axis, a first (optionally, planar) lip portion on one side of and parallel to the channel portion, and a second (optionally, planar) lip portion parallel to and on an opposite side of the channel portion from the first lip portion. Each reflective element is attached to and supported by the lip portions, and bridges the channel portion, of a corresponding one of the longitudinal reflector supports.

In some variations of this aspect, the longitudinal reflector supports are trough shaped. Such a trough shape may have, for example, a V or U shaped cross-section. In some variations, the longitudinal reflector support comprises multiple channel portions (e.g., 2, 3, or more than 3) side-by-side in parallel, between the lip portions. In such variations, the longitudinal reflector support may have, for example, a W shaped cross section or a cross-section that may be viewed as composed of multiple V or U shapes side-by-side.

In further variations comprising the features of any of the above variations of this aspect, the lips and channel portion of each longitudinal reflector support may be formed from a continuous piece of sheet metal.

In further variations comprising the features of any of the above variations of this aspect, the linearly extending reflective elements may be of at least two different lengths and be arranged in parallel side-by side rows, with each row including two or more of the linearly extending reflective elements arranged end-to-end, such that gaps or joints between the reflective elements in one row are not next to gaps or joints between reflective elements in an adjacent row. In some of these variations, no gaps or joints between reflective elements in any row are next to gaps or joints between reflective elements in any adjacent row. In some variations, the majority of gaps or joints between reflective elements in any row are not adjacent to gaps or joints between reflective elements in any adjacent row.

In further variations comprising the features of any of the above variations of this aspect, each linearly extending reflective element may comprise a low-iron glass layer having a first surface and a second surface, with the first surface oriented facing the receiver, a reflective layer disposed on the second surface of the low-iron glass layer, an adhesive disposed on the reflective layer, and a second glass layer attached by the adhesive to the reflective layer, to the low-iron glass layer, or to both the reflective layer and the low-iron glass layer.

In further variations comprising the features of any of the above variations of this aspect, the support structure may comprise a plurality of transverse reflector supports extending away from the rotation axis. Each transverse reflector support may comprise a plurality of notches, with each notch in a transverse reflector support corresponding to a separate longitudinal reflector support. In such variations, the channel portion of each longitudinal reflector support may be positioned in corresponding notches of the transverse reflector supports with the lip portions of each longitudinal reflector support in contact with and supported by surfaces of the transverse reflector supports adjacent to the corresponding notches. The surfaces of the transverse reflector supports adjacent to the corresponding notches may orient the reflective elements with respect to the receiver with a precision of about 0.5 degrees, for example, or better (i.e., tolerance less than about 0.5 degrees).

In further variations comprising the features of any of the above variations of this aspect that comprise transverse reflector supports, the transverse reflector supports may be formed from continuous metal sheets or plates into which the notches are cut, with the plane of the sheets or plates oriented perpendicular to the rotation axis of the support structure.

In further variations comprising the features of any of the above variations of this aspect, the receiver may comprise solar cells. In such variations, the receiver may also comprise coolant channels accommodating flow of liquid coolant in thermal contact with the solar cells. In alternative further variations based on any of the above variations, except for that just preceding this variation, the receiver may accommodate flow of a liquid to be heated by solar energy concentrated on the receiver, but lack solar cells.

In further variations comprising the features of any of the above variations of this aspect, the linear reflective elements may together form a parabolic reflector.

In further variations comprising the features of any of the above variations of this aspect, the linearly extending reflective elements may be flat or substantially flat.

In another aspect, a concentrating solar energy collector comprises a linearly extending receiver, a plurality of linearly extending reflective elements oriented parallel to a long axis of the receiver and fixed in position with respect to each other and with respect to the receiver, and a linearly extending support structure supporting the receiver and the reflective elements and pivotally mounted to accommodate rotation of the support structure, the reflective elements, and the receiver about a rotation axis parallel to the long axis of the receiver. Each linearly extending reflective element comprises a low-iron glass layer having a first surface and a second surface, with the first surface oriented facing the receiver, a reflective layer disposed on the second surface of the low-iron glass layer, an adhesive disposed on the reflective layer, and a second glass layer attached by the adhesive to the reflective layer, to the low-iron glass layer, or to both the reflective layer and the low-iron glass layer.

In some variations of this aspect, the reflective layer is absent from edge portions of the second surface of the low-iron glass layer, the second glass layer is attached directly to the edge portions by the adhesive, and the adhesive on the edge portions seals the reflective layer from an external environment.

In further variations comprising the features of any of the above variations of this aspect, the second glass layer may comprise, for example, soda-lime glass.

In further variations comprising the features of any of the above variations of this aspect, the low-iron glass layer may be about 1 millimeter to about 2 millimeters thick, and the second glass layer may be about 3 to about 4 millimeters thick.

In further variations comprising the features of any of the above variations of this aspect, the linearly extending reflective elements may be flat or substantially flat.

In further variations comprising the features of any of the above variations of this aspect, the linearly extending reflective elements may be of at least two different lengths and be arranged in parallel side-by side rows, with each row including two or more of the linearly extending reflective elements arranged end-to-end, such that gaps or joints between the reflective elements in one row are not next to gaps or joints between reflective elements in an adjacent row. In some of these variations, no gaps or joints between reflective elements in any row are next to gaps or joints between reflective elements in any adjacent row. In some variations, the majority of gaps or joints between reflective elements in any row are not adjacent to gaps or joints between reflective elements in any adjacent row.

In further variations comprising the features of any of the above variations of this aspect, the receiver may comprise solar cells. In such variations, the receiver may also comprise coolant channels accommodating flow of liquid coolant in thermal contact with the solar cells. In alternative further variations based on any of the above variations, except for that just preceding this variation, the receiver may accommodate flow of a liquid to be heated by solar energy concentrated on the receiver, but lack solar cells.

In further variations comprising the features of any of the above variations of this aspect, the linear reflective elements may together form a parabolic reflector.

In further variations comprising the features of any of the above variations of this aspect, the linearly extending reflective elements may be flat or substantially flat.

In another aspect, a concentrating solar energy collector comprises a linearly extending receiver, a plurality of linearly extending reflective elements oriented parallel to a long axis of the receiver and fixed in position with respect to each other and with respect to the receiver, and a linearly extending support structure supporting the receiver and the reflective elements and pivotally mounted to accommodate rotation of the support structure, the reflective elements, and the receiver about a rotation axis parallel to the long axis of the receiver. The linearly extending reflective elements are of at least two different lengths and are arranged in parallel side-by side rows, with each row including two or more of the linearly extending reflective elements arranged end-to-end, such that gaps or joints between the reflective elements in one row are not next to gaps or joints between reflective elements in an adjacent row.

In some of these variations of this aspect, no gaps or joints between reflective elements in any row are next to gaps or joints between reflective elements in any adjacent row. In some variations, the majority of gaps or joints between reflective elements in any row are not adjacent to gaps or joints between reflective elements in any adjacent row.

In further variations comprising the features of any of the above variations of this aspect, the receiver may comprise solar cells. In such variations, the receiver may also comprise coolant channels accommodating flow of liquid coolant in thermal contact with the solar cells. In alternative further variations based on any of the above variations, except for that just preceding this variation, the receiver may accommodate flow of a liquid to be heated by solar energy concentrated on the receiver, but lack solar cells.

In further variations comprising the features of any of the above variations of this aspect, the linear reflective elements may together form a parabolic reflector.

In further variations comprising the features of any of the above variations of this aspect, the linearly extending reflective elements may be flat or substantially flat.

These and other embodiments, features and advantages of the present invention will become more apparent to those skilled in the art when taken with reference to the following more detailed description of the invention in conjunction with the accompanying drawings that are first briefly described.

BRIEF DESCRIPTION OF THE DRAWINGS

FIGS. 1A-1C show perspective (1A), side (1B), and end (1C) views of an example solar energy collector.

FIG. 2 shows a perspective view of an example receiver for a solar energy collector.

FIGS. 3A-3D show perspective (3A), side (3B), top (3C), and cross-sectional (3D) views of a portion of an example support structure for the reflector and receiver of a solar energy collector.

FIGS. 4A-4C show side (4A) and end (4B, 4C) views of examples of a linearly extending reflective element attached to and supported by a longitudinal reflector support.

FIG. 5 shows an example transverse reflector support.

FIGS. 6A and 6B show top views of example reflectors comprising linearly extending reflective elements of two or more lengths.

FIGS. 7A and 7B show example reflective elements (e.g., mirrors) having laminated structures.

FIG. 8 shows an example pivotally mounted support structure comprising a torque tube and transverse reflector supports.

FIG. 9A shows a plan view of an example solar energy collector comprising transverse reflector supports oriented substantially perpendicular to the rotation axis. FIG. 9B shows a plan view of an example solar energy collector comprising transverse reflector supports at least some of which are not oriented perpendicular to the rotation axis.

FIGS. 10A-10C show example geometries of reflective elements arranged end-to-end in a reflector near gaps between the reflective elements.

FIG. 11A shows an example of two solar energy collectors sharing a drive and having fluidly coupled receivers. FIG. 11B shows an expanded view of a detail of the example system shown in FIG. 11A.

DETAILED DESCRIPTION

The following detailed description should be read with reference to the drawings, in which identical reference numbers refer to like elements throughout the different figures. The drawings, which are not necessarily to scale, depict selective embodiments and are not intended to limit the scope of the invention. The detailed description illustrates by way of example, not by way of limitation, the principles of the invention. This description will clearly enable one skilled in the art to make and use the invention, and describes several embodiments, adaptations, variations, alternatives and uses of the invention, including what is presently believed to be the best mode of carrying out the invention.

As used in this specification and the appended claims, the singular forms “a,” “an,” and “the” include plural referents unless the context clearly indicates otherwise. Also, the term “parallel” is intended to mean “substantially parallel” and to encompass minor deviations from parallel geometries rather than to require that parallel rows of reflectors, for example, or any other parallel arrangements described herein be exactly parallel.

This specification discloses apparatus, systems, and methods by which solar energy may be collected to provide electricity, heat, or a combination of electricity and heat. Solar energy collectors as disclosed herein may be used, for example, in some variations of the methods, apparatus, and systems disclosed in U.S. Provisional Patent Application Ser. No. 61/249,151, filed Oct. 6, 2009, titled “Concentrating Solar Photovoltaic-Thermal System,” incorporated herein by reference in its entirety.

Referring now to FIGS. 1A-1C, an example solar energy collector 100 comprises a linearly extending receiver 110, a linearly extending reflector 120 oriented parallel to a long axis 125 of the receiver and fixed in position with respect to the receiver, and a linearly extending support structure 130 supporting the receiver and the reflector and pivotally mounted to accommodate rotation of the support structure, the reflector, and the receiver about a rotation axis 140 parallel to long axis 125 of the receiver. In use, the support structure, reflector, and receiver are rotated about rotation axis 140 to track the sun such that solar radiation incident on reflector 120 is concentrated onto receiver 110.

In the illustrated example, reflector 120 comprises a plurality of linearly extending reflective elements 150 (e.g., mirrors) oriented parallel to the long axis of the receiver and fixed in position with respect to each other and with respect to the receiver. Linear reflective elements 150 may each have a length equal or approximately equal to that of reflector 120, in which case they may be arranged side-by-side to form reflector 120. Alternatively, some or all of linear reflective elements 150 may be shorter than the length of reflector 120, in which case (e.g., as illustrated) two or more linearly extending reflective elements 150 may be arranged end-to-end to form a row along the length of the reflector, and two or more such rows may be arranged side-by-side to form reflector 120.

Linearly extending reflective elements 150 may each have a width, for example, of about 8 centimeters to about 15 centimeters, and a length, for example, of about 1.2 meters to about 3.2 meters. In some variations, some or all of reflective elements 150 have a width of about 10.7 centimeters. In some variations, some or all of reflective elements 150 have a width of about 13.2 centimeters. In some variations, some of reflective elements 150 have a width of about 10.7 centimeters and some of reflective elements 150 have a width of about 13.2 centimeters. Reflective elements 150 may be flat, substantially flat, or curved (e.g., along a direction transverse to their long axes to focus incident solar radiation).

Although in the illustrated example reflector 120 comprises linearly reflective elements 150, in other variations reflector 120 may be formed from a single continuous reflective element, from two reflective elements (e.g., one on each side of receiver 110), or in any other suitable manner.

Linear reflective elements 150, or other reflective elements used to form a reflector 120, may be or comprise, for example, any suitable front surface mirror or rear surface mirror. The reflective properties of the mirror may result, for example, from any suitable metallic or dielectric coating or polished metal surface. Some variations may utilize a mirror having a laminated structure as described later in this specification. Some other variations may utilize a rear surface mirror formed with low-iron glass having a thickness of about 3 to about 4 millimeters.

In some variations, reflector 120 has a parabolic curvature transverse to its long axis. In alternative variations, reflector 120 may have any other curvature suitable for concentrating solar radiation onto a receiver.

In the example illustrated in FIGS. 1A-1D as well as in FIG. 2, receiver 110 comprises two sections (e.g., individual receivers) 110 a and 110 b mechanically coupled to each other to form a V-shape and supported above reflector 120 by vertical supports 160. As shown in FIG. 2, the V-shaped arrangement of receiver sections 110 a, 110 b may optionally be stabilized by brackets 165 coupled to rods 170 attached to underlying vertical supports 160. In the illustrated example (e.g., FIG. 1A), reflective elements on one side of receiver 110 form a parabolic section of reflector 120 having a substantially linear focus on and parallel to the lower surface of receiver section 110 a, and reflective elements on the other side of receiver 110 form a parabolic section of reflector 120 having a substantially linear focus on and parallel to the lower surface of receiver section 110 b.

Referring again to FIGS. 1A-1D and FIG. 2, in the illustrated example lower surfaces 180 a and 180 b of receiver sections 110 a, 110 b comprise solar cells (not shown) to be illuminated by solar radiation concentrated by reflector 120. As shown in FIG. 2, junction boxes 175 or other electrical components associated with the solar cells may be located on rear surfaces of receiver sections 110 a, 110 b opposite to the surfaces on which solar radiation is concentrated. Liquid coolant (e.g., water, ethylene glycol, or a mixture of the two) may be introduced into and removed from receiver sections 110 a, 110 b, through manifolds 185 on the rear surfaces of the receiver section. Coolant introduced at one end of a receiver section may pass through one or more coolant channels (not shown) to the other end of the receiver section from which the coolant may be withdrawn. This may allow the receiver to produce electricity more efficiently (by cooling the solar cells) and to capture heat (in the coolant). Both the electricity and the captured heat may be of commercial value.

Although receiver 110 has a V-shape in the illustrated example, other variations may use other receiver geometries. Some variations may use a horizontally oriented receiver. For example, one or more receivers of the form of receiver 110 a or 110 b may be positioned horizontally above and parallel to reflector 120 and rotation axis 140. In use, their lower horizontal surfaces would be illuminated from below by solar radiation concentrated by reflector 120.

Although receiver sections 110 a, 110 b in the illustrated example comprise solar cells and coolant channels accommodating flow of liquid coolant in thermal contact with the solar cells, other arrangements may also be used. In some variations of the solar energy collector, the receiver comprises solar cells but lacks channels through which a liquid coolant may be flowed. In other variations of the solar energy collector, the receiver may comprise channels accommodating flow of a liquid to be heated by solar energy concentrated on the receiver, but lack solar cells. For example, receiver sections 110 a, 110 b may comprise solar cells but lack coolant channels, or lack solar cells but comprise coolant channels.

Solar energy collector 100 may comprise any suitable receiver. In addition to the illustrated examples, suitable receivers may include, for example, those disclosed in U.S. patent application Ser. No. 12/622,416, filed Nov. 19, 2009, titled “Receiver For Concentrating Photovoltaic-Thermal System;” and U.S. patent application Ser. No. 12/774,436, filed May 5, 2010, also titled “Receiver For Concentrating Photovoltaic-Thermal System;” both of which are incorporated herein by reference in their entirety.

In the illustrated example, receiver 110 is shorter than reflector 120. At one end of solar energy collector 100 (e.g., the support post 200 a end), the end of receiver 110 is positioned approximately in line with the end of reflector 120. In contrast, at the other end of solar energy collector 100 (e.g., the support post 200 b end), receiver 110 does not extend to the end of reflector 120. In some of such variations, the receiver is shorter than the reflector by, for example, about 2% to about 5% of the length of the reflector.

A solar energy collector having such a configuration may be oriented with its rotation axis 140 along a North-South direction, and with the end of the solar energy collector at which the receiver does not extend to the end of the reflector closer to the equator than is the other end of the solar energy collector. Because, except at the equator, solar radiation will have a daily and seasonally varying North-South component to its angle of incidence on reflector 120, portions of receiver 110 too close to the equator end of the collector would not be illuminated by concentrated solar radiation, or would be illuminated by solar radiation for a significantly shorter portion of a day, or of a year, than other portions of the receiver. That phenomenon may be avoided or diminished with the illustrated configuration. Alternatively, or in addition, in some variations receiver 110 may extend beyond the end of reflector 120 at the end of solar energy collector 100 farthest from the equator (i.e., the polar end), and hence collect concentrated solar radiation that would otherwise have missed the end of the receiver. In some of the latter variations, the receiver may be longer than the reflector by, for example, about 2% to about 5% of the length of the reflector.

In some variations, in use, a receiver is illuminated by concentrated solar radiation that under-fills the receiver. For example, more than about 80%, more than about 85%, more than about 90%, or more than about 95% of the energy of the concentrated solar radiation may be incident on the receiver in a region having a width (transverse to the long axis of the receiver) that is about 75%, about 80%, about 85%, about 90%, or about 95% of the overall width of the receiver (or of that portion of the receiver comprising solar cells). In some variations at least about 90%, or at least about 95% of the solar energy incident on the solar cells is concentrated on a central portion of the linear array of solar cells having a width, perpendicular to the long axis of the array of solar cells, of less than about 80% of the corresponding width of the linear array of solar cells. Under-filling the receiver in this manner may increase the efficiency with which concentrated solar radiation is collected and converted to useful electricity or heat.

Such under-filling may be accomplished, for example, by selecting the width of linearly extending reflective elements 150 (and their transverse curvature, if they are not flat or substantially flat) to provide the desired concentrated solar radiation intensity distribution on the illuminated receiver surface.

Referring yet again to FIGS. 1A-1D, in the illustrated example support structure 130 is pivotally mounted at its ends by slew gear 190 and bearing 195 supported by, respectively, support posts 200 a and 200 b. Slew gear 190 may be used to rotate receiver 110, reflector 120, and support structure 130 around rotation axis 140. Because support structure 130 is supported only at its ends (where the support posts do not obstruct rotation of receiver 110 and reflector 120), in some variations receiver 110, reflector 120, and support structure 130 may be rotated into a completely inverted position with receiver 110 and reflector 120 upside-down. In that orientation, receiver 110 and reflector 120 may be protected, or partially protected, from adverse weather conditions, for example. In some such variations, receiver 110, reflector 120, and support structure 130 may be rotated by 360 degrees or more around rotation axis 140. In addition, use of only two support posts, rather than more, may relax tolerance requirements in their placement and alignment.

Any suitable slew gear and bearing may be used in the illustrated example. Other variations may utilize any suitable alternative mounting arrangement that allows receiver 110, reflector 120, and support structure 130 to be rotated around a rotation axis parallel to a long axis of the receiver, the reflector, or (as illustrated) the receiver and the reflector to track the sun.

FIGS. 3A-3D show a portion of an example support structure 130. In that example, support structure 130 comprises three longitudinal members 210 a, 210 b, and 210 c oriented parallel to the rotation axis, extending at least substantially the length of the reflector, and arranged to form a framework having a triangular cross-section (e.g., FIG. 3D) perpendicular to rotation axis 140.

In the illustrated example, longitudinal member 210 b is coincident or substantially coincident with rotational axis 140 and located on the reflective side (e.g., the receiver side) of reflector 120. Longitudinal members 210 a and 210 c are located on the opposite side of reflector 120 from longitudinal member 210 b. In other variations, rotational axis 140 may, for example, lie within, or outside of, the triangular cross-section of the framework formed by longitudinal members 210 a-210 c. In some variations, all three of longitudinal members 210 a-210 c may be located below reflector 120 (i.e., on the opposite side of reflector 120 from receiver 110).

The illustrated example comprises a plurality of diagonal members 215 connecting longitudinal member 210 b to longitudinal member 210 a, and a plurality of diagonal members 220 connecting longitudinal member 210 b to longitudinal member 210 c. The illustrated example also comprises a plurality of transverse plates 225. Each transverse plate 225 is oriented perpendicular to (or substantially perpendicular to) and connecting the three longitudinal members 210 a-210 c. Diagonals 215 each connect a joint 230 between a corresponding transverse plate 225 and longitudinal member 210 b to a joint 235 between an adjacent transverse plate 225 and longitudinal member 210 a. Diagonals 225 each connect a joint 230 between a corresponding transverse plate 225 and longitudinal member 210 b to a joint 240 between an adjacent transverse plate 225 and longitudinal member 210 c. Transverse plates 225, diagonals 215, and diagonals 220 together form a repeating pattern 245 along the length of longitudinal members 210 a-210 c.

Other variations of support structure 130 may include diagonal members, but lack transverse plates, or include transverse plates, but lack diagonal members. Some variations may include transverse plates and diagonals without those elements forming a repeating pattern, or with them forming a repeating pattern different from that illustrated. In some variations, each transverse plate 225 may be replaced by three transverse members, each of which connects a different pair of the longitudinal members 210 a-210 c.

Some variations comprise, in addition to diagonals 215, diagonals 220, and transverse plates 225 as shown in the illustrated example, longitudinal plates spanning the gap between and connecting longitudinal members 210 a and 210 c. In some variations, two or more such plates are positioned approximately end to end along longitudinal members 210 a and 210 c to close substantially all of the gap between those members. The addition of such longitudinal plates may increase the stiffness of support structure 130.

Longitudinal members 210 a-210 c, diagonals 215, and diagonals 220 may be formed, for example, from steel, structural steel, or aluminum beams, hollow beams, tubes, pipes, bars, rods, channel stock, angle stock, or any other suitable material in any other suitable shape. Transverse plates 225 may be formed, for example, from steel, structural steel, or aluminum plates, sheets, or any other suitable material.

Longitudinal members 210 a-210 c, diagonals 215, diagonals 220, and plates 225 may be attached to each other as illustrated, for example, using any suitable method. Suitable methods may include, for example, welding, gluing, or use of any suitable clamp, screw, bolt, rivet, or other mechanical fastener.

Some variations of support structure 130 do not comprise longitudinal members 210 a-210 c. As described later in this specification, for example, some variations may substitute a torque tube for the portion of support structure 130 shown in FIGS. 3A-3D. Any other suitable reflector support structure may also be substituted for the illustrated structure and used in combination with the other elements of the solar energy collectors disclosed herein.

As described in more detail below, support structure 130 may comprise longitudinal reflector supports each of which has a long axis oriented parallel to the rotation axis 140 and each of which supports a linearly extending reflective element 150, or a row of linearly reflective elements 150 arranged end-to-end. The linearly extending reflective element or elements may be attached, for example, to an upper surface of the longitudinal reflector support. Also as described in more detail below, support structure 130 may comprise transverse reflector supports extending away from the rotation axis 140 and supporting the longitudinal reflector supports or, alternatively, directly support mirrors or other reflective elements.

Referring now to FIGS. 4A (side view) and 4B (end or cross-sectional view), an example longitudinal reflector support 250 comprises a channel portion 255 parallel to its long axis, a first planar lip portion 260 a on one side of and parallel to channel portion 255, and a second planar lip portion 260 b parallel to and on an opposite side of channel portion 255 from the first lip portion 260 a. Linearly extending reflective elements 150 are attached to and supported by lip portions 260 a, 260 b, and bridge channel portion 255, of longitudinal reflector support 250. In other variations, lip portions 260 a and 260 b need not be planar, as illustrated. Any suitable profile or shape for lip portions 260 a, 260 b may be used.

In the example illustrated in FIGS. 4A and 4B, linearly extending reflective elements 150 are attached to lip portions 260 a, 260 b by adhesive or glue pads 265. The adhesive or glue pads may be spaced, for example, at intervals of about 0.2 meters under the reflective elements. Any other suitable method of attaching the reflective elements to the longitudinal reflector support may be used, including adhesives or glues deployed in any other suitable manner, screws, bolts, rivets and other similar mechanical fasteners, and clamps or spring clips.

In the illustrated example, longitudinal reflector support 250 is about 11.2 meters long, channel portion 255 extends the length of longitudinal reflector support 250 and is about 10.5 centimeters wide and about 3.5 centimeters deep, and lip portions 260 a and 260 b extend the length of longitudinal reflector support 250 and are about 2.0 centimeters wide. Linearly extending reflective elements 150 are about 10.7 centimeters wide in this example. Two or more longitudinally reflective elements are attached end-to-end along a longitudinal reflector support with a spacing of about 1 millimeter between reflective elements. In other variations, such longitudinal reflector supports may be, for example, about 6.0 meters to about 12.0 meters long, channel portions 255 may be about 8 centimeters to about 15 centimeters wide and about 2.0 centimeters to about 8.0 centimeters deep, and lip portions 260 a, 260 b may be about 1.0 centimeters to about 4.0 centimeters wide.

Referring now to FIG. 4C, in another example a longitudinal reflector support 265 is substantially similar to longitudinal reflector support 250 just described, except that longitudinal reflector support 265 further comprises slot portions 270 a, 270 b at the ends of lip portions 260 a, 260 b. In this example, linearly extending reflective elements 150 may be loaded onto longitudinal support 265 by sliding the reflective elements in from the end of the reflector support. Slot portions 270 a, 270 b help maintain linearly extending reflective elements 150 in position. Adhesives, glues, clamps, or mechanical fasteners, for example, may be used to further secure the reflective elements to the reflector supports.

In the illustrated examples, the longitudinal reflector supports are trough shaped with a cross section having a flat-bottomed “U” shape. In other variations, the longitudinal reflector supports may be trough shaped with, for example, a rounded bottom “U” shape cross-section, a “V” shape cross-section, or an upside-down Ω (Greek letter Omega) cross-section. In other variations, the longitudinal reflector support may comprise multiple channel portions (e.g., 2, 3, or more than 3), side-by-side in parallel, between lip portions 260 a, 260 b. In such variations, the longitudinal reflector support may have, for example, a W shaped cross section or a cross-section that may be viewed as composed of multiple V or U shapes side-by-side.

In the illustrated example, individual longitudinal reflector supports extend the length of the reflector. In other variations, some or all of the longitudinal reflector supports may be shorter than the overall length of the reflector, in which case two or more longitudinal reflector supports may be arranged end-to-end to form a row along the length of the reflector.

Longitudinal reflector supports may be formed, in some variations, from sheet steel, sheet aluminum, or other sheet metals. In some variations (such as those illustrated in FIGS. 4A-4C, for example), the lips and channel portion (and slot portions, if present) of a longitudinal reflector support may be rolled, folded, or otherwise formed from a continuous piece of sheet metal. In some variations, the lips and channel portion of a longitudinal reflector support as illustrated are formed from a continuous sheet of steel having a thickness of about 1 millimeter.

As noted above, support structure 130 may comprise a plurality of transverse reflector supports that extend away from the rotational axis 140 and directly support mirrors or other reflective elements or, alternatively, support mirrors or reflective elements via longitudinal reflector supports as disclosed herein or via any other suitable additional reflector support structure. Such transverse reflector supports, designated by reference numeral 275, are partially visible in FIGS. 1A-1C.

Referring now to FIG. 5, an example transverse reflector support 275 comprises two (e.g., symmetrical) plates 280 a, 280 b, each of which has, respectively, an upper notched edge 285 a, 285 b. Optionally, plates 280 a, 280 b are folded along edges 290 a, 290 b to form an upward-facing u-shape channel section running parallel to those edges. In the illustrated example, transverse reflector support 275 also comprises an optional cross member 295 partially inserted (as shown by dashed lines) into lower channel sections of plates 280 a, 280 b and coupling those plates to each other. Portions of surfaces 300 a and 300 b adjacent to the notches in plates 280 a, 280 b may be cut to define desired orientations of linearly extending reflective elements to be supported by the transverse reflector support.

Transverse plates 280 a, 280 b of transverse reflector supports 275 may be formed, for example, from continuous metal (e.g., steel, aluminum) sheets or plates into which the notches are cut.

In the illustrated example, transverse reflector supports 275 may be attached to corresponding ones of transverse plates 225 (FIG. 3A), for example, by welding, gluing, or use of any suitable clamp, screw, bolt, rivet or other mechanical fastener. Such fasteners may use holes 305 in plates 280 a, 280 b (FIG. 5) for example.

In the example illustrated in the various figures, support structure 130 (FIGS. 1A-1C) comprises a plurality of transverse reflector supports 275. Each notch in an upper surface of a transverse reflector support 275 (FIG. 5) corresponds to a separate longitudinal reflector support 250 or 265 (FIG. 4). Each notch in a transverse reflector support 275 is aligned with a similarly or identically placed notch (corresponding to the same longitudinal reflector support) in the other transverse reflector supports. The channel portions 255 of the longitudinal reflector supports are positioned in corresponding notches of the transverse reflector supports. The lip portions 260 a, 260 b of the longitudinal reflector supports are then in contact with and supported by portions of surfaces 300 of the transverse reflector supports adjacent to the corresponding notches. Surfaces 300 may orient the longitudinal reflector supports, and thus the linearly extending reflective elements 150 they support, in a desired orientation with respect to receiver 110 with a precision of about 0.5 degrees, for example, or better (i.e., tolerance less than about 0.5 degrees). In other variations, this tolerance may be, for example, greater than about 0.5 degrees.

Longitudinal reflector supports 250 or 265 may be attached to transverse reflector supports 275 or to other portions of support structure 130, for example, by welding, gluing, or use of any suitable clamp, screw, bolt, rivet or other mechanical fastener. In some variations, the longitudinal reflector supports are clamped at their ends (e.g., only at their ends) to another portion of support structure 130.

Although particular examples of longitudinal reflector supports and transverse reflector supports are illustrated and described herein, any other suitable reflector supports or reflector structures may be used in combination with the other elements of the solar energy collectors disclosed herein.

As noted above, in some variations reflector 120 (FIG. 1A) comprises linear reflective elements arranged end-to-end in rows (e.g., of equal length) along the length of the reflector, with two or more such rows arranged side-by side. In such variations, the linear reflective elements may be of two or more different lengths and arranged such that gaps or joints between the reflective elements in one row are not next to gaps or joints between reflective elements in an adjacent row. In some variations, no gaps or joints between reflective elements in any row are next to gaps or joints between reflective elements in any adjacent row. In some variations, the majority of gaps or joints between reflective elements in any row are not adjacent to gaps or joints between reflective elements in any adjacent row.

In the example of FIG. 6A, a reflector 120 comprises two different lengths of linearly extending reflective elements, as exemplified by reflective elements 150 a and 150 b. In the arrangement of linearly extending reflective elements in this example, each gap or joint (e.g., 310 a) is separated from the next nearest gap or joint (e.g., 310 b) in the direction transverse to the long axis of reflector 120 by at least one row of linearly extending reflective elements.

In the example of FIG. 6B, a reflector 120 comprises three different lengths of linearly extending reflective elements, as exemplified by reflective elements 150 c, 150 d, and 150 e. In the arrangement of linearly extending reflective elements in this example, each gap or joint (e.g., 310 c) is separated from the next nearest gap or joint (e.g., 310 d) in the direction transverse to the long axis of reflector 120 by at least two rows of linearly extending reflective elements.

Linearly extending reflective elements may be arranged in a manner substantially similar to the examples of FIGS. 6A and 6B, using a larger number of different lengths of reflective elements, to construct reflectors having a correspondingly larger number of rows between gaps.

Arrangements such as those just described may produce a more uniform illumination of the receiver by concentrated solar radiation than would occur if gaps or joints between reflective elements in rows were generally next to gaps or joints in adjacent rows, because such adjacent gaps or joints might cast shadows that were superimposed on each other on the receiver.

Also as noted above, in some variations linearly extending reflective elements 150 have a laminated structure. Referring to FIG. 7A, in the illustrated example reflective element 150 comprises a low-iron glass layer 320 having a first surface 322 and a second surface 323. When in use in a solar energy collector as disclosed herein, reflective element 150 is oriented so that surface 322 faces the receiver (and hence the incident solar radiation). A reflective layer 325 is disposed on the second surface of the low-iron glass layer. An adhesive layer 330 is disposed on the reflective layer. A second glass layer 335 is attached by adhesive layer 330 to reflective layer 325.

In the example illustrated in FIG. 7B, reflective layer 325 is absent from edge portions (e.g., around the entire periphery of reflective element 150) of the second surface 323 of low-iron glass layer 320. Adhesive layer 330 attaches corresponding edge portions (e.g., around the entire periphery of reflective element 150) of second glass layer 335 directly to the exposed edge portions of surface 323, and attaches other portions of second glass layer 335 to reflective layer 325. In this example, adhesive layer 330, in combination with glass layers 320 and 335, may seal and/or protect reflective layer 325 from the external environment.

Low-iron glass layer may be, for example, about 0.5 millimeters to about 3 millimeters thick. Reflective layer 325 may comprise, for example, silver, gold, chrome, or any other suitable metal or non-metal material or materials and be, for example, about 20 nanometers to about 200 nanometers thick. Adhesive layer 325 may comprise, for example, an acrylic closed-cell foam adhesive tape (e.g., VHB™ tape available from 3M™), and be, for example, about 0.5 millimeters to about 1.5 millimeters thick. Second glass layer 335 may comprise, for example, soda lime glass or borosilicate glass and be, for example, about 2 millimeters to about 5 millimeters thick. In one example, low-iron glass layer 320 is about 1 millimeter thick, reflective layer 325 comprises silver and is about 80 nanometers thick, adhesive layer 330 comprises acrylic closed-cell foam tape and is about 0.9 millimeters thick, and second glass layer 335 comprises soda lime glass and is about 4 millimeters thick.

Reflective layer 325 may be deposited and patterned (e.g., its edges removed), and adhesive layer 330 deposited, by conventional processes, for example.

As noted above, some variations of the solar energy collectors disclosed herein may substitute a torque tube for the portion of support structure 130 shown in FIGS. 3A-3D. In the example of FIG. 8, a torque tube 340 is pivotally supported by support posts 350 a, 350 b, and 350 c. Transverse reflector supports 275, which may be substantially similar to those described above, are attached to torque tube 340. Longitudinal reflector supports 250 or 265, as described above, with attached linearly extending reflective elements 150, may be installed on transverse reflector supports 275 to provide a reflector 120 identical or substantially similar to those described above. A receiver, substantially similar to those described above, may be supported by vertical supports 160 above the reflector.

FIG. 9A shows a plan view of an example solar energy collector 100 comprising rows of linearly extending reflective elements 150 supported by transverse reflector supports 275 that are oriented substantially perpendicular to rotation axis 140. If linearly extending reflective elements 150 and any underlying longitudinal support are insufficiently stiff, the rows of reflective elements 150 may droop (i.e., sag) between transverse reflector supports 275. This drooping may cause non-uniformity in the intensity distribution of solar radiation concentrated by the reflective elements on a receiver. Because the transverse reflector supports 275 are oriented perpendicular to the rows of reflective elements 150, the drooping may occur at similar or the same locations along the different rows of reflective elements, which may increase the non-uniformity of the concentrated solar radiation intensity distribution at the receiver.

Referring now to the plan view of FIG. 9B, in other variations some or all of transverse reflector supports 275 are oriented at an angle with respect to the rotation axis other than 90°. FIG. 9B shows only a single example of the many such possible configurations. In such arrangements, any drooping of the rows of reflective elements 150 will likely occur at different locations along each row, diminishing any resulting non-uniformity of the concentrated solar radiation intensity distribution at the receiver.

As noted above, gaps between reflective elements in a solar energy collector may cause shadows that produce non-uniform illumination of the receiver. Referring to FIG. 10A, for example, light rays 370 a, 370 b incident on ends of reflective elements 150 adjacent to gap 310 are reflected in parallel and hence cast a shadow 380 because no light is reflected from gap 310.

In some variations, such shadows may be attenuated or blurred by shaping the ends of reflective elements 150 adjacent the gap to spread reflected light into what would otherwise be a shadow. Referring to FIGS. 10B and 10C, for example, ends of reflective elements 150 adjacent the gap may curve or bend downward into gap 310 (i.e., away from the incident light). In such variations, light rays 370 a, 370 b are reflected in a crossing manner that spreads reflected light into what would otherwise be a shadow 380 (FIG. 10A). Such shaping of the ends of reflective elements 150 may be accomplished, for example, by positioning underlying support structure such that the force of gravity draws the ends of the reflective elements into the desired shape. Alternatively, linear reflective elements 150 may be attached to underlying support structure that applies a force to induce such a shape, or linear reflective elements 150 may be formed to inherently have such a shape. Any suitable manner of shaping the ends of reflective elements 150 to attenuate shadows cast by gaps between the reflective elements may be used.

Two or more solar energy collectors as disclosed herein may be electrically, fluidly, and/or mechanically coupled to each other and may, for example, share a drive mechanism. Referring now to FIGS. 11A and 11B, for example, two aligned solar energy collectors 100 a, 100 b may share, and be driven by, a single slew gear 190. Solar energy collectors 100 a, 100 b may be substantially similar to any of the solar energy collectors disclosed herein.

In the example illustrated in FIGS. 11A and 11B, conduit 415 a fluidly couples receiver section 110 a of solar energy collector 100 b to the corresponding receiver section in solar energy collector 100 a, and conduit 415 b similarly fluidly couples receiver section 110 b in solar energy collector 100 b to the corresponding receiver section in solar energy collector 100 a. Conduits 415 a, 415 b allow coolant from one solar energy collector to be transferred to the other for further heating, for example.

In the illustrated example, conduits 415 a and 415 b are straight connections between the adjacent solar energy collectors, with the conduits located at approximately the positions of the linear foci of the reflectors in the solar energy collectors. In such variations, concentrated solar radiation may be incident on and absorbed by conduits 415 a, 415 b. In some such variations, solar energy collectors 100 a, 100 b are configured and oriented (e.g., with rotation axis oriented North-South) such that, over time (e.g., during the course of a day or a year), solar radiation concentrated by reflectors in the solar energy collectors walks onto or off of the conduits. This can occur, for example, as the angle of the sun above the horizon varies during the course of a day or a year and the linear foci of reflectors oriented in a North-South direction move along a North-South axis. In some variations, conduits 415 a, 415 b may receive greater concentrated solar radiation during the winter than during the summer. In some variations, as the angle of the sun above the horizon decreases (e.g., during the course of a day or a year), concentrated solar radiation walks off conduits 415 a, 415 b onto an adjacent end of a receiver.

In some variations, conduits 415 a, 415 b are glazed, e.g., enclosed in a substantially transparent outer tube or shell (not shown), with an optional air gap between the conduit and the outer tube or shell. Such a tube or shell may be formed, for example, from glass or plastic. Glazing the conduits may enhance retention of heat in coolant flowing through the conduits, and may also provide for further collection of heat from solar radiation incident on the conduits. In some variations in which the conduits are glazed, the conduits are coated, painted (e.g., with black paint) or otherwise treated to increase absorption of solar radiation. Such treating, coating, or painting of the conduits to increase absorption of solar radiation may also be utilized in variations in which the conduits are not glazed.

In some variations, conduits 415 a, 415 b are insulated to enhance retention of heat. Any suitable insulation may be used.

Use of conduits such as 415 a and 415 b, whether straight or otherwise, is optional.

In the example of FIGS. 11A and 11B, each receiver 110 comprises receiver sections 110 a, 110 b mechanically coupled to form a V-shape. Each receiver 110 also comprises a cover 410 extending parallel to the rotation axis and positioned horizontally above receiver sections 110 a, 110 b. Cover 410 may close and (optionally) seal the top of the V-shape. Similar or identical covers may be utilized with other solar energy collectors disclosed herein, as well, particularly with any of the solar energy collectors disclosed herein comprising V-shaped receivers. The use of such covers, or of additional solar energy receiver sections in their place, is further described in U.S. patent application Ser. No. 12/774,436, filed May 5, 2010, titled “Receiver For Concentrating Photovoltaic-Thermal System.”

This disclosure is illustrative and not limiting. Further modifications will be apparent to one skilled in the art in light of this disclosure and are intended to fall within the scope of the appended claims. 

What is claimed is:
 1. A concentrating solar energy collector comprising: a linearly elongated reflector having a linear focus; a linearly elongated receiver oriented parallel to the linear focus of the reflector and fixed in position with respect to the reflector, the receiver comprising solar cells that in operation of the solar energy collector are illuminated by solar radiation concentrated by the reflector onto the receiver; and a support structure supporting the reflector and the receiver and pivotally mounted to accommodate rotation of the support structure, the reflector, and the receiver about a rotation axis parallel to the linear focus of the reflector; wherein the reflector comprises a plurality of linearly elongated reflective elements each having a long axis, and the linearly elongated reflective elements are arranged in two or more parallel side-by-side rows with the rows and the long axes of the linearly elongated reflective elements oriented parallel to the linear focus of the reflector; wherein each row of linearly elongated reflective elements includes two or more of the linearly elongated reflective elements arranged end-to-end such that gaps or joints between the linearly elongated reflective elements in each row are not next to gaps or joints between linearly elongated reflective elements in an adjacent row; and wherein in each row of linearly elongated reflective elements arranged end-to-end each gap or joint between linearly elongated reflective elements is separated from its nearest neighbor gap or joint in the other rows of linearly elongated reflective elements by at least one row of linearly elongated reflective elements.
 2. The concentrating solar energy collector of claim 1, wherein the linearly elongated reflective elements are of two different lengths.
 3. The concentrating solar energy collector of claim 1, wherein in each row of linearly elongated reflective elements arranged end-to-end each gap or joint between linearly elongated reflective elements is separated from its nearest neighbor gap or joint in the other rows of linearly elongated reflective elements by at least two rows of linearly elongated reflective elements.
 4. The concentrating solar energy collector of claim 3, wherein the linearly elongated reflective elements are of three different lengths.
 5. The concentrating solar energy collector of claim 1, wherein the linearly elongated reflective elements are flat or substantially flat transverse to their long axes.
 6. The concentrating solar energy collector of claim 1, wherein the reflector has a parabolic curvature transverse to the long axis of the receiver.
 7. The concentrating solar energy collector of claim 1, wherein the receiver comprises coolant channels accommodating flow of liquid coolant in thermal contact with the solar cells.
 8. The concentrating solar energy collector of claim 1, wherein the receiver comprises a lower surface oriented horizontally above the reflector to receive solar radiation concentrated by the reflector.
 9. The concentrating solar energy collector of claim 1, wherein the receiver comprises first and second lower surfaces arranged to form a V-shape above the reflector, with a section of the reflector on one side of the receiver arranged to focus solar radiation onto the first surface and a section of the reflector on the other side of the receiver arranged to focus solar radiation onto the second surface.
 10. The concentrating solar energy collector of claim 1, wherein the support structure comprises a torque tube extending along the rotation axis and a plurality of transverse reflector supports extending away from the rotation axis to support the reflector.
 11. The concentrating solar energy collector of claim 10, wherein the support structure comprises a slew gear at an end of the torque tube, the slew gear driving rotation of the reflector, the receiver, and the support structure about the rotation axis.
 12. The concentrating solar energy collector of claim 11, wherein the slew gear is shared with and also drives rotation of another solar energy collector.
 13. The concentrating solar energy collector of claim 1, wherein: the receiver comprises a lower surface oriented horizontally above the reflector to receive solar radiation concentrated by the reflector; the linearly elongated reflective elements are flat or substantially flat transverse to their long axes; and the reflector has a parabolic curvature transverse to the long axis of the receiver.
 14. The concentrating solar energy collector of claim 13, wherein the receiver comprises coolant channels accommodating flow of liquid coolant in thermal contact with the solar cells.
 15. The concentrating solar energy collector of claim 13, wherein the linearly elongated reflective elements are of two different lengths.
 16. The concentrating solar energy collector of claim 13, wherein in each row of linearly elongated reflective elements arranged end-to-end each gap or joint between linearly elongated reflective elements is separated from its nearest neighbor gap or joint in the other rows of linearly elongated reflective elements by at least two rows of linearly elongated reflective elements.
 17. The concentrating solar energy collector of claim 16, wherein the linearly elongated reflective elements are of three different lengths.
 18. The concentrating solar energy collector of claim 13, wherein the support structure comprises: a torque tube extending along the rotation axis and a plurality of transverse reflector supports extending away from the rotation axis to support the reflector; and a slew gear at an end of the torque tube, the slew gear driving rotation of the reflector, the receiver, and the support structure about the rotation axis.
 19. The concentrating solar energy collector of claim 18, wherein the slew gear is shared with and also drives rotation of another solar energy collector.
 20. The concentrating solar energy collector of claim 19, wherein the receiver comprises coolant channels accommodating flow of liquid coolant in thermal contact with the solar cells. 